Abstract: A method for determining a time of contact of a capacitive sensor includes continuously measuring a capacitance value of the capacitive sensor and processing the measured capacitance value into a digital sensor signal. The sensor signal is filtered to output a filter signal. Initial dynamics of the filter signal are identified upon the filter signal exceeding a first set filter threshold value. A time at which the filter signal falls below a second set filter threshold value is determined as being a potential time of contact of the capacitive sensor. An actual time of contact of the capacitive sensor is determined when the sensor signal relative to an offset of the sensor signal exceeds a sensor signal threshold value. The offset of the sensor signal is a value of the sensor signal prior to the contact of the capacitive sensor.

Abstract: Embodiments relate to a device (20), a method and a computer program for providing information on at least one sequence, wherein the at least one sequence describes temporally successive signal states, comprising a device (10), a method and a computer program for a cytometer (100) for providing information on one or several cells in a medium in a channel and comprising a cytometer (100). The device (20) comprises an interface (22), which is configured to receive information on a number of the signal states. The device (20) a computational module (24) which is configured to generate a plurality of possible sequences based on the information on the number of the signal states. The computational module (24) is further configured to calculate for at least a subset of the possible sequences correlation functions between a sequence and at least a temporal scaling of the sequence, wherein a correlation function includes a main lobe and one or several side lobes.

Abstract: A method for determining a time of contact of a capacitive sensor includes continuously measuring a capacitance value of the capacitive sensor and processing the measured capacitance value into a digital sensor signal. The sensor signal is filtered to output a filter signal. Initial dynamics of the filter signal are identified upon the filter signal exceeding a first set filter threshold value. A time at which the filter signal falls below a second set filter threshold value is determined as being a potential time of contact of the capacitive sensor. An actual time of contact of the capacitive sensor is determined when the sensor signal relative to an offset of the sensor signal exceeds a sensor signal threshold value. The offset of the sensor signal is a value of the sensor signal prior to the contact of the capacitive sensor.

Abstract: The present invention concerns a method of detecting particles which move along a trajectory and which produce or at least influence electromagnetic radiation, an electrical field or a magnetic field, wherein the electromagnetic radiation, the electrical field or the magnetic field is detected, in which a structuring device is used, which either ensures that the particles along the trajectory produce or at least influence electromagnetic radiation, an electrical field or a magnetic field substantially only at non-periodic spatial spacings, or ensures that the electromagnetic radiation, the electrical or the magnetic field is detected substantially only at non-periodic spatial spacings along the trajectory.

Abstract: The present invention concerns a method of detecting particles which move along a trajectory and which produce or at least influence electromagnetic radiation, an electrical field or a magnetic field, wherein the electromagnetic radiation S, the electrical field or the magnetic field is detected, in which a structuring device is used, which either ensures that the particles along the trajectory produce or at least influence electromagnetic radiation, an electrical field or a magnetic field substantially only at non-periodic spatial spacings, or ensures that the electromagnetic radiation S, the electrical or the magnetic field is detected substantially only at non-periodic spatial spacings along the trajectory.